High energy collision of two particles in wormhole spacetimes

Tsukamoto, Naoki; Bambi, Cosimo

doi:10.1103/physrevd.91.084013

Cited by 32 publications

(14 citation statements)

References 84 publications

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“…(17), (18) for the metric below). Astrophysical significance of this situation is still unclear, but it can happen, in particular, for wormholes [26]- [29]. In this limit both for massless (4) and massive (13) fragments we find that the maximum energy at infinity is given by the same formulae (5) and (14), so that…”

Section: Diverging Metric Coefficientmentioning

confidence: 66%

“…Using the expressions for sin θ L , cos θ L , sin θ , cos θ from (52,53,59,60), the definitions of E, P, P r , P φ , M from Eqs. (24)(25)(26)(27)(28)(29)(30)(31)(32), and some more algebra, we can obtain θ E ≡ θ L + θ :…”

Section: Discussionmentioning

confidence: 99%

“…It is clear from Eqs. (26), (30) and (32) that for the same energies and angular momenta of the colliding particles, the energy in the center of mass frame is greater when they are traveling in the opposite directions in the radial coordinate. Indeed, when Z 1 Z 2 < 0, the absolute values of Z 0 and P are less than when Z 1 Z 2 > 0, while X 0 and E stay the same, which leads to greater M in (32).…”

Section: B Particles In Locally Non-rotating Framementioning

confidence: 99%

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Collisional super-Penrose process and Wald inequalities

Tanatarov

Заславский

2017

Gen Relativ Gravit

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We consider collision of two massive particles in the equatorial plane of an axially symmetric stationary spacetime that produces two massless particles afterwards. It is implied that the horizon is absent but there is a naked singularity or another potential barrier that makes possible the head-on collision. The relationship between the energy in the center of mass frame E c.m. and the Killing energy E measured at infinity is analyzed. It follows immediately from the Wald inequalities that unbounded E is possible for unbounded E c.m. only. This can be realized if the spacetime is close to the threshold of the horizon formation. Different types of spacetimes (black holes, naked singularities, wormholes) correspond to different possible relations between E c.m. and E. We develop a general approach that enables us to describe the collision process in the frames of the stationary observer and ZAMO (zero angular momentum observer). The escape cone and escape fraction are derived. A simple explanation of the existence of the bright spot is given. For the particular case of the Kerr metric, our results agree with the previous ones found in M. Patil, T. Harada, K. Nakao, P.S. Joshi, and M. Kimura, Phys. Rev. D 93, 104015 (2016

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Section: Diverging Metric Coefficientmentioning

confidence: 66%

Section: Discussionmentioning

confidence: 99%

Section: B Particles In Locally Non-rotating Framementioning

confidence: 99%

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Collisional super-Penrose process and Wald inequalities

Tanatarov

Заславский

2017

Gen Relativ Gravit

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“…First of all, this includes wormholes. For the first time, high energy collisions in wormhole space-times were considered in [6] where it was shown for a particular model (the Teo wormhole [7]) that unbounded E c.m. is possible.…”

mentioning

confidence: 99%

“…To achieve our goal, it is necessary that particle 3 escape to infinity without reflection from the potential barrier back to the vicinity of the throat, so that the expression inside the radical in (6) should be positive everywhere. Then, the condition under discussion reads Z 2 > 0, where Z is given by (6). To simplify formulas, let us assume that m 3 = 0 or negligible.…”

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confidence: 99%

Super-Penrose process and rotating wormholes

Заславский

2018

Phys. Rev. D

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We consider collision of particles in a wormhole near its throat. Particles come from the opposite mouths. If the lapse function is small enough there, the energy E of debris at infinity grows unbounded, so we are faced with the so-called super-Penrose process. This requires the existence of the ergoregion, so a wormhole should be rotating. PACS numbers: 04.70.Bw, In recent years, essential interest revived to high energy collisions in a strong gravitation field. This concerns the behavior of two different characteristics -the energy E c.m. in the center of mass frame of colliding particles and/or the Killing energy E of debris measured at infinity. The first quantity can become arbitrarily large in the test particle approximation.This was found in [1] (the so-called BSW effect) for the extremal Kerr metric that provoked a huge series of works in which the BSW effect was generalized. In spite of unbounded E c.m. , the quantity E remains quite modest after collisions near black holes because of strongThis stimulates search for other types of objects such that E (in the test particle approximation) could be formally unbounded after collision (this is called the super-Penrose process). First of all, this includes wormholes. For the first time, high energy collisions in wormhole space-times were considered in [6] where it was shown for a particular model (the Teo wormhole [7]) that unbounded E c.m. is possible. It turned out that unbounded E are possible as well [8]. It was revealed that there is a general underlying reasons both for * Electronic address: zaslav@ukr.net

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Astrophysical Signatures of Thin Accretion Disks in Wormhole Spacetimes

Harkó

Kovács²

2017

Fundamental Theories of Physics

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High energy collision of two particles in wormhole spacetimes

Cited by 32 publications

References 84 publications

Collisional super-Penrose process and Wald inequalities

Collisional super-Penrose process and Wald inequalities

Super-Penrose process and rotating wormholes

Astrophysical Signatures of Thin Accretion Disks in Wormhole Spacetimes

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